Oct 23, 2009 - 4Department of Physics, Florida State University, Tallahassee, Florida 32306, USA. 5Nuclear Engineering Division, Argonne National ...
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PHYSICAL REVIEW C 80, 041304(R) (2009)
Wobbling mode in 167 Ta D. J. Hartley,1 R. V. F. Janssens,2 L. L. Riedinger,3 M. A. Riley,4 A. Aguilar,4,* M. P. Carpenter,2 C. J. Chiara,2,5,6 P. Chowdhury,7 I. G. Darby,3 U. Garg,8 Q. A. Ijaz,9 F. G. Kondev,5 S. Lakshmi,7 T. Lauritsen,2 A. Ludington,1,† W. C. Ma,9 E. A. McCutchan,2 S. Mukhopadhyay,8 R. Pifer,1 E. P. Seyfried,1 I. Stefanescu,2,6 S. K. Tandel,7 U. Tandel,7 J. R. Vanhoy,1 X. Wang,4 S. Zhu,2 I. Hamamoto,10 and S. Frauendorf 8 1
Department of Physics, U.S. Naval Academy, Annapolis, Maryland 21402, USA Physics Division, Argonne National Laboratory, Argonne, Illinois 60439, USA 3 Department of Physics and Astronomy, University of Tennessee, Knoxville, Tennessee 37996, USA 4 Department of Physics, Florida State University, Tallahassee, Florida 32306, USA 5 Nuclear Engineering Division, Argonne National Laboratory, Argonne, Illinois 60439, USA 6 Department of Chemistry and Biochemistry, University of Maryland, College Park, Maryland 20742, USA 7 Department of Physics, University of Massachusetts Lowell, Lowell, Massachusetts 01854, USA 8 Department of Physics, University of Notre Dame, Notre Dame, Indiana 46556, USA 9 Department of Physics, Mississippi State University, Mississippi State, Mississippi 39762, USA 10 Department of Mathematical Physics, LTH, University of Lund, Lund, Sweden (Received 10 August 2009; revised manuscript received 8 September 2009; published 23 October 2009; corrected 28 October 2009) 2
The collective wobbling mode, the strongest signature for the rotation of a triaxial nucleus, has previously been seen only in a few Lu isotopes in spite of extensive searches in nearby isotopes. A sequence of transitions in the N = 94 167 Ta nucleus exhibiting features similar to those attributed to the wobbling bands in the Lu nuclei has now been found. This band feeds into the π i13/2 band at a relative energy similar to that seen in the established wobbling bands and its dynamic moment of inertia and alignment properties are nearly identical to the i13/2 structure over a significant frequency range. Given these characteristics, it is likely that the wobbling mode has been observed for the first time in a nucleus other than Lu, making this collective motion a more general phenomenon. DOI: 10.1103/PhysRevC.80.041304
PACS number(s): 21.10.Re, 23.20.Lv, 27.70.+q
Our understanding of the wobbling mode in nuclei (and the associated stable triaxial deformation) has evolved quickly over the past decade. Bohr and Mottelson [1] first proposed that the rotation of a stable triaxially deformed nucleus would result in the presence of wobbling excitations. These excitations occur because the rotational angular momentum is not aligned with any of the body-fixed axes; rather it precesses and wobbles around one of these axes in a manner similar to that of an asymmetric top. In 1995, Schnack-Petersen et al. [2] first suggested that rotational bands based on proton i13/2 excitations in 163,165 Lu are associated with a triaxial strongly deformed (TSD) potential well. The large deformation is mainly due to the occupation of the intruder i13/2 orbital, and the triaxial deformation (γ = 20◦ ) results from an N = 94 shell gap that develops with enhanced quadrupole deformation (�2 ≈ 0.37). No direct experimental evidence for triaxiality was observed until the wobbling mode was confirmed in 163 Lu by Ødeg˚ard et al. [3]. This seminal work established the existence of a band feeding into the π i13/2 structure where the two sequences have nearly identical moments of inertia and alignments over a large frequency range. The similarities of the moments of
*
Present address: Department of Radiation Oncology, University of Pennsylvania, Philadelphia, Pennsylvania 19104, USA. † Present address: Department of Nuclear Engineering, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA. 0556-2813/2009/80(4)/041304(5)
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inertia and alignments are a predicted feature for a wobbling band as the intrinsic structure for both bands should be the same; the only difference between the two is the degree to which the rotational angular momentum vector lies off axis. The collective wobbling behavior can thus be described within a phonon model, where the energy of each band is h ¯2 I (I + 1) + h ¯ ωw (nw + 1/2), where h ¯ ωw = equal to E = 2J � h ¯ ωrot (Jx − Jy )(Jx − Jz )/(Jy Jz ) [1]. The nw = 0 phonon number is assigned to the energetically lowest band in the family, as its angular momentum vector lies closest to a body axis, and in the case of the Lu isotopes, this is associated with the π i13/2 band. Wobbling excitations with nw = 1, 2, 3, etc. then follow, each lying successively higher in energy as the rotational angular momentum vector progressively lies farther from the body axis with increasing nw . Indeed, Jensen et al. [4] not only confirmed the nw = 1 sequence in 163 Lu but also observed the nw = 2 structure. Perhaps most importantly, Ødeg˚ard et al. [3] obtained polarization results for the linking transitions from the nw = 1 to the nw = 0 structure which confirmed that the �I = 1 transitions are primarily of E2 character. This signature cannot be accounted for in normal cranking calculations, but it is expected for the wobbling mode [3]. Only a few years later, examples of wobbling were found in the N = 94 165 Lu [5] and N = 96 167 Lu [6] isotopes. This led to the assertion that “the wobbling mode is a general phenomenon in this region” [5]. However, subsequent studies in many neighboring Hf [7], Tm [8,9], and Ta [10,11] nuclei failed to generate any further examples of wobbling. These ©2009 The American Physical Society
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FIG. 1. (a) Spectrum of band TSD 1 (π i13/2 ) in 167 Ta created by summing all possible combinations of triple gates on inband transitions. Peaks denoted with triangles are transitions from known states in 167 Ta; those labeled with a cross are linking transitions. (b) Spectrum of band TSD 2 (nw = 1 sequence) resulting from a sum of all combinations of the 517-keV γ ray in the i13/2 band with any two inband transitions. Peaks labeled with a filled circle are from the i13/2 band.
observations led to the suggestion that wobbling is not a general phenomenon to be observed in this region, but rather that the Lu isotopic chain is perhaps the only one suited to exhibit this mode. Indeed, the tilted-axis cranking calculations by Frauendorf, given in Ref. [8], indicate that the density of states in the Lu TSD minimum is sufficiently low that the high-excitation energy of the wobbling mode can be observed. In contrast, a much higher density of states is found in TSD minima of Ta and other nuclei, which could produce many TSD bands based on alternative particle-hole configurations. Thus, it is not that wobbling bands are absent in these nuclei; rather, the competition between this collective mode and the particle-hole excitations greatly favors the population of the latter. This provided the motivation for an experiment producing 167 Ta94 to search for either wobbling bands based on the π i13/2 orbital or multiple particle-hole TSD bands. The 120 Sn(51 V,4n) reaction was used with a 51 V beam accelerated to 235 MeV by the ATLAS facility at Argonne National Laboratory. Two self-supporting 120 Sn targets were stacked, each with a thickness of 500 µg/cm2 . A total of 101 Compton-suppressed germanium detectors was included in the Gammasphere array [12]. Approximately 2 × 109 four-fold or greater coincidence events were recorded in five days of beam time. The data were sorted into a Blue database [13] such that RADWARE [14] coincidence cubes and hypercubes could be generated. In addition, angular-correlation ratios were obtained from the database using the background-subtraction method of Starosta et al. [15]. The ratios were determined by Rang = W (θf , φ)/W (θ90◦ , φ), where W (θf , φ) is the intensity observed in the forward detectors (θ = 122◦ , 130◦ , 143◦ , 148◦ , and 163◦ ) and W (θ90◦ , φ) is the intensity observed in the Gammasphere rings near 90◦ (θ = 79◦ , 81◦ , 90◦ , 99◦ , and 101◦ ). Normalized ratios of approximately 0.6 and 1.0 were observed for known stretched E1 and E2 transitions, respectively. If wobbling exists in 167 Ta, it would likely be based on the π i13/2 orbital (in analogy with the Lu isotopes), but this
structure had not yet been identified [16]. Figure 1(a) displays the spectrum of a new band in 167 Ta. Coincidence triple gates were placed on all possible combinations of the marked peaks in a hypercube to generate the spectrum. Transitions decaying to previously known states in 167 Ta were identified, and a partial level scheme is presented in Fig. 2 where this new band is labeled as TSD 1. The angular-correlation analysis indicates that the 500-, 527-, and 772-keV transitions feeding into the [404]7/2 and [402]5/2 structures are of E2 character with ratio values of 1.04(4), 0.96(3), and 1.06(8), respectively. Therefore, the spins and parity of this new band have been firmly established as given in Fig. 2. The fragmented decay to the [402]5/2, [411]1/2, and [404]7/2 structures is reminiscent of the π i13/2 bands observed in heavier Ta nuclei [10,11] as well as in the N ≈ 94 Lu nuclei [3,5,6]. In addition, the large dynamic moment of inertia (with respect to the other sequences in 167 Ta) of this band and its large initial alignment of ∼6¯h provide strong arguments that this structure is associated with the π i13/2 orbital. The excitation energy of this band is also consistent with the theoretical estimates for the i13/2 structure of Ref. [17]. As previously stated, an nw = 1 wobbling sequence is expected to have a moment of inertia nearly identical to that of the nw = 0 band (i.e., the i13/2 band). Therefore, a search was performed for bands with γ -ray energy spacings similar to those of band TSD 1. A sample spectrum, obtained as a sum of coincidence spectra requiring the presence of the 517-keV transition in TSD 1 together with any two inband transitions in the new sequence, is presented in Fig. 1(b). This new band was added to Fig. 2, where it is labeled TSD 2. It is noteworthy that this TSD 2 sequence decays solely into band TSD 1 through linking transitions for which the angular-correlation measurements indicate �I = 1 character, with values of 0.50(8) and 0.71(8) for the 643- and 632-keV transitions, respectively. The positive parity for the TSD 2 levels is proposed based on the exclusive feeding of the i13/2 sequence. Band TSD 2 will be associated with the wobbling mode based on arguments outlined below. In addition, another sequence
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FIG. 2. Partial level scheme for (TSD 2).
PHYSICAL REVIEW C 80, 041304(R) (2009)
167
Ta displaying the newly observed π i13/2 (TSD 1) band and the proposed nw = 1 wobbling structure
(Band 3) was observed to feed the i13/2 band, as displayed in Fig. 2. The spin of this sequence was also determined by angular correlation ratios of 1.03(6) and 1.05(6) for the
764- and 796-keV transitions, respectively. This structure is nearly degenerate with TSD 1 and appears to be strongly related to the i13/2 configuration as well.
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FIG. 4. (Color online) Excitation energy minus a rigid-rotor reference for denoted bands in (a) 167 Ta and its isotone (b) 165 Lu [5]. The inertia parameter A was set to 0.007 MeV/¯h2 . The π h11/2 bands are shown for both nuclei as they are the energetically lowest structures.
60 0.2 0.3 0.4 0.5 0.6
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h− ω (MeV) FIG. 3. (Color online) Alignment vs rotational energy for bands TSD 1 (π i13/2 ) and TSD 2 (nw = 1) in (a) 167 Ta and (b) 165 Lu [5]. ¯ 2 /MeV and J1 = 40 h ¯ 4 /MeV3 Harris parameters [18] of J0 = 25 h were used as a reference. Dynamic moments of inertia for the same bands in (c) 167 Ta and (d) 165 Lu.
The multiple linking transitions from band TSD 2 to the i13/2 band (TSD 1) lead to the suggestion that the two bands likely share a similar structure. Thus, two interpretations must be considered for the former sequence. First, it is possible that this band is the unfavored signature partner of the i13/2 sequence. However, it is well known that unfavored signatures of high-j orbitals are characterized by significantly smaller alignments than those seen in the favored partners. Clearly, this is not the case, as can be seen in Fig. 3(a): Band TSD 2 has a slightly higher alignment than the i13/2 band (TSD 1). Ultimate cranker (UC) calculations also indicate that the unfavored signature of the i13/2 band has an excitation energy in the rotating frame (Routhian) approximately 1 MeV higher than that of the favored signature partner. Conversely, band TSD 2 has a Routhian that lies at most ∼350 keV above the TSD 1 sequence. For these reasons, an interpretation in terms of an unfavored signature partner does not properly describe the observations. The second interpretation for TSD 2 is that it is a wobbling sequence. Inspection of Fig. 3(a) indicates that these two bands have alignments that are quite similar above 0.4 MeV and are only separated by ∼1¯h below this frequency. The moments of inertia are very close as well at high frequency [Fig. 3(c)]. These similarities compare favorably with the properties of the previously established TSD bands in 165 Lu [5] displayed in Fig. 3(b) and 3(d), where TSD 2 is the nw = 1 wobbling structure. In addition, the energy separation between the bands in 167 Ta mirrors that seen between the wobbling excitation and the i13/2 structure in 165 Lu, as can be seen in Fig. 4. Therefore, band TSD 2 is a strong candidate for the first nw = 1 wobbling band observed in a nucleus other than those in the Lu chain. However, an intriguing feature is observed in the dynamic moment of inertia plot displayed in Fig. 3(c). An interaction is
found just above 0.35 MeV in TSD 1 that is absent in TSD 2. This is the same frequency region where band TSD 1 gains approximately 1¯h with respect to TSD 2, as seen in Fig. 3(a). This effect is magnified in Fig. 5, which displays the relative alignments between the nw = 1 wobbling bands and the i13/2 structures upon which they are based for 163,165,167 Lu and 167 Ta. No such alignment gain is observed in 163,165 Lu, as the relative alignments are nearly constant at approximately −0.4¯h. Yet, in 167 Lu and 167 Ta, a similar gain of approximately 1¯h is noted and 167 in Ta a constant relative alignment near −0.4¯h is achieved at the highest frequencies, a value similar to that seen in 163,165 Lu. It is possible that the interactions found in the A = 167 nuclei are the result of the i13/2 orbital transitioning from a γ = 0◦ strongly deformed (SD) prolate minimum to the TSD minimum. The frequency and rate at which this transition occurs are sensitive to the detailed structure of the individual nuclei; therefore, it is not unexpected that the relative
FIG. 5. (Color online) Relative alignment [�ix = ix (TSD 1) −ix (TSD 2)] vs the rotational frequency of band TSD 1 in the four nuclei denoted. Dashed lines are placed at �ix = −0.4¯h.
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alignments for the Lu and Ta nuclei would behave somewhat differently. Band TSD 1 will display such an interaction (since this is the sequence in which the change is occurring), whereas TSD 2 is not affected as it only exists in the TSD minimum. If this hypothesis is correct, Band 3 in Fig. 2 may well represent the continuation of the i13/2 sequence in the γ = 0◦ SD minimum. Its alignment values [Fig. 3(a)] and excitation energy [Fig. 4(a)] indicate that bands TSD 1 and 3 lie along a similar trajectory before the interaction occurs near 0.35 MeV (I = 51/2). A detailed lifetime experiment is required to validate this interpretation as the quadrupole moments of the individual states should decrease in TSD 1 as the spin increases through the interaction region, owing to the cos(30◦ + γ ) dependence [1]. Perhaps the most rigorous means to identify a wobbling sequence is to determine the nature of the transitions from the nw = 1 structure to the nw = 0 band. The wobbling interpretation requires these transitions to be of the �I = 1 type, with a dominant E2 character, as found in 163 Lu [3]. Experimental proof requires polarization measurements, which could not be accomplished in the present experiment. Nevertheless, because of the similarity between the linking transitions in 167 Ta and those in 163,165,167 Lu (in terms of energy and branching ratio), it is reasonable to assume that they also share similarities in their electromagnetic characteristics. Thus, a mixing ratio where the linking transitions are approximately 90% E2 (the value measured in 163 Lu [3]) has been assumed for those found in 167 Ta. The corresponding B(E2)out /B(E2)in ratios were then determined for the 39/2, 43/2, and 47/2 states to be 0.37(4), 0.32(4), and 0.36(4), respectively. These experimental values are large, indeed much larger than possible with any cranking interpretation [B(E2)out /B(E2)in � 0.01]. They also exceed the predictions of the particle-rotor model (which decrease
from 0.267 to 0.224 in this spin region) and the values found in the Lu isotopes (∼0.2). The differences may result from the fact that, in the spin region of the linking transitions, the two sequences are possibly in different potential minima (as described here). It is also possible that the triaxial deformation is larger in 167 Ta compared to its Lu neighbors, as the ratio is proportional to [sin(30◦ + γ )/cos(30◦ + γ )]2 [19]. However, UC calculations suggest that both Lu and Ta TSD minima are located near γ = 20◦ . Finally, the assumption that the linking transitions are 90% E2 in character may be an overestimate and a reduction in this value would decrease the B(E2)out /B(E2)in ratio. In summary, high-spin rotational band structures have been identified in the N = 94 nucleus 167 Ta, including the π i13/2 sequence. A new band with nearly identical dynamic moment of inertia and alignment properties above a frequency of 0.4 MeV has been observed that feeds into the latter. These features along with branching ratio measurements of the inband to out-of-band transitions are characteristic of the wellestablished wobbling bands in Lu isotopes. Thus, we suggest that the wobbling mode has been observed for the first time in a nucleus other than Lu.
[1] A. Bohr and B. R. Mottelson, Nuclear Structure, Vol. II (Benjamin, Reading, MA, 1975). [2] H. Schnack-Petersen et al., Nucl. Phys. A594, 175 (1995). [3] S. W. Ødeg˚ard et al., Phys. Rev. Lett. 86, 5866 (2001). [4] D. R. Jensen et al., Phys. Rev. Lett. 89, 142503 (2002). [5] G. Sch¨onwaßer et al., Phys. Lett. B552, 9 (2003). [6] H. Amro et al., Phys. Lett. B553, 197 (2003). [7] Y. C. Zhang et al., Phys. Rev. C 76, 064321 (2007). [8] N. S. Pattabiraman et al., Phys. Lett. B647, 243 (2007). [9] C. Teal et al., Phys. Rev. C 78, 017305 (2008). [10] D. J. Hartley et al., Phys. Rev. C 72, 064325 (2005). [11] D. J. Hartley et al., Phys. Rev. C 74, 054314 (2006).
[12] R. V. F. Janssens and F. S. Stephens, Nucl. Phys. News 6, 9 (1996). [13] M. Cromaz et al., Nucl. Instrum. Methods A 462, 519 (2001). [14] D. C. Radford, Nucl. Instrum. Methods A 361, 297 (1995). [15] K. Starosta et al., Nucl. Instrum. Methods A 515, 771 (2003). [16] K. Theine et al., Nucl. Phys. A536, 418 (1992). [17] W. Nazarewicz, M. A. Riley, and J. D. Garrett, Nucl. Phys. A512, 61 (1990). [18] S. M. Harris, Phys. Rev. 138, B509 (1965). [19] I. Hamamoto and G. B. Hagemann, Phys. Rev. C 67, 014319 (2003).
The authors thank the ANL operations staff at Gammasphere and gratefully acknowledge the efforts of J. P. Greene for target preparation. We also thank D. C. Radford and H. Q. Jin for their software support. This work is funded by the National Science Foundation under Grant Nos. PHY-0554762 (USNA), PHY-0456463 (FSU), and PHY-0754674 (UND), as well as by the US Department of Energy, Office of Nuclear Physics, under Contract Nos. DE-AC02-06CH11257 (ANL), DE-FG02-94ER40848 (UML), and DE-FG02-96ER40983 (UT).
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